KR20210096198A - Security pattern capable of writing variable encoding information, manufacturing method and device therefor - Google Patents

Abstract

The present invention provides a security pattern capable of writing variable encoding information, and a method and apparatus for manufacturing the same, wherein the manufacturing apparatus includes a coating printing apparatus, a transmission apparatus, a laser array light source, and an induced magnetic field, the induced magnetic field and the transmission The devices are synchronized. The present invention uses a laser array light source to output an optical signal, the light source is programmable, variable, has a high degree of refinement, and can output a more detailed pattern, and the point light source array can be controlled by a program, a program can be controlled, and variable codes can be manufactured accordingly. A crawler-type magnetic field is used to induce induction in the pattern transmission process, and the conveyor-type synchronous induction method takes longer induction time than other methods and produces a more stable pattern.

Description

Security pattern capable of writing variable encoding information, manufacturing method and device therefor

The present invention belongs to the field of anti-counterfeiting printing technology, and in particular, relates to a security pattern capable of writing variable encoding information, and a method and apparatus for manufacturing the same.

In October 2015, the People's Bank of China issued a 100 yuan banknote with a new anti-counterfeiting function, which was completed in cooperation with JDSU, Sicpa and KBA. In 2002, M Seto, T Tiller and E Miller of SICPA HOLDING SA, a shareholder of sicpa, issued Chinese Patent 02800567.8 "Magnetic thin film interference device or pigment and manufacturing method thereof, printing ink or paint composition comprising such a magnetic thin film interference device. , confidential documents and applications" disclosed the anti-counterfeiting function, which is currently used worldwide; It is worth mentioning that the key elements of the present technology are the printing pattern and the magnetic pattern.

The present invention is to develop an anti-counterfeiting security pattern having both a primary effect and a secondary machine-readable effect.

It is an object of the present invention to be realized through the following technical solutions.

A security pattern in which variable encoding information can be written includes a plurality of regions hardened in different directions, and some or all of the plurality of regions include variable encoding information.

An apparatus for manufacturing a security pattern capable of writing variable encoding information, the apparatus comprising:

a coating printing apparatus, a substrate transfer apparatus, an N group point light source array, an N or N+1 group magnetic field, and one endpoint curing light source, wherein N=1; the N group point light source array and the N or N+1 group magnetic field are provided on the same side or opposite sides of the substrate transfer direction;

the coating printing device is used to coat and print a pattern on the substrate surface;

the substrate transfer device is used to transfer a pattern-coated substrate; Since each point light source array controls the illumination range and illumination brightness according to the real-time encoding information, the light signal corresponding to the encoding information is output as a coated printed pattern on the substrate that enters the irradiation range of the point light source array. and the ink in the corresponding area on the coated printed pattern is exposed and cured;

Each magnetic field is used to induce ink in the uncured portion of the coated printed pattern, all of which change its angle;

After the N group point light source array and the N or N+1 group magnetic field are installed, the end-point curing light source is used to cure all uncured portions of the pattern to realize complete exposure of the pattern.

The N group point light source array and the N or N+1 group magnetic field are installed on opposite sides in the substrate transfer direction, so that the N group point light source array is all installed above or below the substrate, and correspondingly, The magnetic fields of the N or N+1 group indicate that all of the magnetic fields are installed on the lower side or the upper side of the substrate.

Specifically, depending on the direction in which the substrate is transferred, the point light source array and the magnetic field are installed at intervals one by one, between each two adjacent group point light source arrays, and between the last one group point light source array and the end point curing light source. , when the number of magnetic fields is N+1 group, one group of magnetic fields is installed before the first group point light source array.

Preferably, depending on the direction in which the substrate is transmitted, the heads of each magnetic field all overlap or partially overlap with the nearest array of point light sources. The purpose of this design is that the orientation after induction can be maintained when the ink is cured after the magnetic field is induced, and the orientation is not disturbed or obscured by demagnetization. Another option is that the magnetic field and the point light source array do not overlap at all. The advantage of this design is that the action of the magnetic field and the point light source array on the ink in the coated printed pattern does not affect each other.

Preferably, the magnetic field is a stationary magnetic field or a synchronous magnetic field transmitted synchronously with the substrate.

Preferably, the synchronous magnetic field is formed to be secured to a flexible conveyor belt using an induction magnet or electromagnetic clamping clamp, and aimed at the coated printed pattern on the substrate.

Preferably, the synchronous magnetic field uses a plurality of magnetic field complex superposition schemes, and the magnetic force range of the magnetic field has a different magnetic moment depending on the size and position of the magnetic field, and according to the principle, a small magnetic field of a short distance over an existing long distance In addition, the effect of the complex magnetic field is acquired.

Preferably, the minimum distance between the coated printed pattern and the magnetic field is 0.1MM-10CM.

Preferably, the point light source array comprises an encoding mechanism and an exposure mechanism, wherein the encoding mechanism is used to generate encoding information, and the exposure mechanism determines an illumination range and an illumination brightness of the point light source array according to the encoding information. used to control; The corresponding point light source is a single or a plurality of point light sources, and through translation and/or switching in a two-dimensional plane, a corresponding portion of the pattern of the substrate surface is exposed and cured.

Preferably, the point light source array is a point laser light source array.

Preferably, each laser tube in said point laser light source array controls switching and adjusts energy intensity, all through circuitry; The equivalent diameter or length of a rectangular side of a single point laser source uses a range of 10ηM-10MM. The laser is fired from the laser tube, coupled to the optical fiber through a coupler, and again through a collimating lens to perform zero-angle collimation to the light exit angle to improve the boundary sharpness of the pattern.

Preferably, the point laser light source array is a two-dimensional array light source or a one-dimensional line array.

Preferably, the point light source array is a controllable point light source array, wherein the collecting, collimating or projecting of each controllable point light source all controls switching through a circuit; For the equivalent diameter of a single point light source or the length of the rectangular side, use the range 10ηM-10MM.

Preferably, the point light source array further comprises a controllable light barrier installed between the point light source array and the substrate, and when the light source of the point light source array does not change, by controlling the degree of opening of the controllable light barrier, , it is possible to realize exposure control of the point light source array.

In one embodiment, the number of point light source arrays is two, all of which are installed on the upper side of the substrate, and the number of synchronous magnetic fields is two, all of which are installed on the lower side of the substrate;

The substrate transfer device is used to transfer a coated printed substrate within an irradiation range of a first point light source array, and the first point light source array includes, according to encoding information, a first area shape to be displayed on a coated printed pattern and used to output an optical signal corresponding to a light-dark pattern, and after the first area of the coated printed pattern is exposure-cured, the substrate transfer device continues to transmit the substrate, and the first synchronization magnetic field is the first synchronization moved synchronously with the substrate by a magnetic field transmission device, wherein the first synchronous magnetic field is used to induce an uncured portion of the coated printed pattern, ie, ink other than the first area, to change the angle;

The substrate transfer device is also used to transfer the substrate after the first region is cured into an irradiation range of a second point light source array, wherein the second point light source array is displayed in a coated printed pattern according to the encoding information. outputting an optical signal corresponding to the shape of the second region and the light and dark pattern, and used for exposing and curing the second region of the coated printed pattern after the first synchronous magnetic field is applied;

The substrate transfer device is also used to transfer the substrate into the irradiation range of the endpoint curing light source after the second point light source array acts, in this process, a second synchronous magnetic field is generated by the second synchronous magnetic field transfer device moving synchronously with the substrate, the second synchronous magnetic field is used to induce ink in an uncured portion of the coated printed pattern, that is, in an area other than the first area and the second area, to change the angle; The endpoint curing light source is used for exposure curing the area after the second synchronous magnetic field has been applied.

The present invention also provides a method of manufacturing a security pattern capable of writing variable encoding information,

adding the inducible material to the coating printing ink paint and coating printing on the substrate to form a light cured coating printed pattern; At the same time, the N group point light source array and the N or N+1 group magnetic field are provided, and the N group point light source array and the N or N+1 group magnetic field are installed on the same side or opposite sides of the substrate transmission direction, N=1, step (S1);

When the substrate is transferred, and the quantity of the magnetic field is N+1 groups, in the process of transferring the substrate, the magnetic field of the first group first induces the coated printed pattern, and the coated printed pattern is again converted to the first point. transmitted within the irradiation range of the light source array, and when the quantity of the magnetic field is N group, the coated printed pattern is directly transmitted into the irradiation range of the first point light source array, and the first point light source array is a pattern light source according to the encoding information forming a, and the pattern light source exposes the coated printed pattern within the irradiation range of the point light source array to cure a portion corresponding to the pattern light source among the coated printed patterns, and the pattern of the pattern light source is coated with the printed pattern to achieve the effect of transitioning to a pattern, a step (S2);

The substrate is continuously transferred, during which a magnetic field corresponding to the coated printed pattern induces an uncured portion of the coated printed pattern to reach within the irradiation range of the next encodeable point light source array, The encodeable point light source array forms another pattern light source according to the encoding information, and the other pattern light source exposes the coated printed pattern within the irradiation range of the point light source array to light the other one of the coated printed patterns. curing the portion corresponding to the pattern light source of the step (S3) and;

If necessary, step S4, repeating step S3 until the substrate sequentially passes through the N group point light source array and the N or N+1 group magnetic field;

The coating-printed pattern is continuously transmitted within the irradiation range of the end-point curing light source, and includes a step (S5) of curing all of the uncured portion of the coating-printed pattern.

Another method of manufacturing a security pattern capable of writing variable encoding information,

A substrate is provided having a coated printed pattern, wherein the coated printed pattern is in a cured state; The used coating printing ink paint has a liquefaction action with respect to the light source, that is, the exposed portion of the coating printed pattern is changed from a polymer to a low molecular weight, that is, from a solid state to a liquid state; At the same time, it provides a pattern liquefied light source, a magnetic field and an endpoint curing mechanism, wherein the pattern liquefied light source encodeably controls the illumination range and illumination brightness of the light source, thereby generating a liquefied light source pattern, wherein the magnetic field is installed in the pattern liquefied light source Then, the magnetic field is a magnetic field that moves synchronously with the substrate or a fixed magnetic field, step (S1);

The coating printed pattern on the substrate is transferred within the irradiation range of the pattern liquefied light source, and the liquefied light source pattern is transferred to the coated printed pattern, and the region corresponding to the liquefied light source pattern among the coated printed patterns is in a liquid state. changing. step (S2) and;

The substrate is continuously transferred, and in the process of transferring, the magnetic field induces a coated printed pattern of the substrate, thereby re-inducing the direction of the ink paint after liquefaction (S3);

and the substrate is continuously transferred within the working range of the end point solidification mechanism, and the area after being induced again is hardened to form a new pattern (S4).

In summary, the present invention draws attention to the following key points.

1. The synchronous induction mechanism is fixed to the flexible conveyor belt using an induction iron or electromagnetic clamping clamp, and aimed at the coated printed pattern on the substrate; When working, the coated printed pattern and the underlying magnetic induction are transmitted at the same synchronous line speed.

2. Fabrication in liquefied light state: first move the induction cured pattern to the liquefied light area, irradiate the light, then transfer the pattern of the light source to the coated printed pattern waiting for exposure, liquefy the exposed part, and then By re-inducing the material of the liquefied portion, the angle or shape of the material inside the liquefied portion pattern is deflected or changed, and cured again, so that writing of the digital pattern can be completed.

3. Complex magnetic field: The induction of the magnetic field can use a method of combining a plurality of magnetic fields, the magnetic force range of the magnetic field varies according to the size and position of the magnetic field, and the magnetic moment is different; According to this principle, the effect of a complex magnetic field can be obtained by adding a small magnetic field of a short distance to the existing long-distance.

4. Using a light source with encoding controllable, exposure curing can be performed on the coated printed substrate through translation and switching in a two-dimensional plane through a point light source to form a corresponding fixed or variable pattern. there is.

5. Ink for coating printing used The paint must have a curing or liquefaction action on the light source, that is, in the exposed range, the coated printed pattern is changed from low molecular weight to high molecular weight, or from high molecular weight to low molecular weight. A new pattern may be exhibited by first inducing the material and changing the liquid state to a solid state again, or by changing from a solid state to a liquid state and changing it back to a solid state after induction.

Compared with the prior art, the present invention has the following advantages.

1. The present invention performs optical signal output using a laser array light source, the light source can be formed by encoding a light pattern, has the advantage of being variable and high in detail, and can output a more detailed pattern, The light source of the array can be programmatically controlled, thus creating a variable code.

2. A crawler-type magnetic field is used to induce induction during the pattern transmission process, and the conveyor-type synchronous induction method takes longer induction time than other methods and can produce more stable patterns.

1 is a schematic diagram of a security pattern in each step of Embodiment 1 of the present invention.
2 is a schematic diagram of a security pattern in each step of Embodiment 1 of the present invention.
3 is a schematic diagram of a security pattern in each step of Embodiment 1 of the present invention.
4 is a schematic diagram of a security pattern in each step of Embodiment 1 of the present invention.
5 is a schematic diagram of a security pattern in Embodiment 2 of the present invention.
6 is a schematic diagram of a security pattern in Embodiment 3 of the present invention.
7 is a schematic diagram of a pattern of each step in Example 4 of the present invention.
8 is a schematic diagram of a pattern of each step in Example 4 of the present invention.
9 is a schematic diagram of a pattern of each step in Example 4 of the present invention.
Fig. 10 is a schematic diagram of the principle of the manufacturing apparatus according to the first embodiment of the present invention.
11 is a schematic diagram of the principle of a manufacturing apparatus according to Example 5 of the present invention.

Example 1:

The present embodiment provides a security pattern capable of writing variable encoding information, an apparatus for manufacturing the same, and a manufacturing method thereof.

A security pattern capable of writing variable encoding information used in an ink layer pattern for coating printing, wherein the ink layer pattern for coating printing includes a first region, a second region and a third region formed by step-by-step exposure curing, wherein Region 1 is an overlapping portion of the second region and the third region, and the curing directions of the coating printing inks in the three regions are all different.

As shown in FIG. 10 , the manufacturing apparatus includes a coating printing apparatus, a substrate transfer apparatus 1 , a first group point laser light source array 2 , a first magnetic field 3 , a first magnetic field transfer apparatus 31 , a second group point laser light source array 4 , a second magnetic field 5 , a second magnetic field transmission device 51 and a curing light source 6 .

The coating printing apparatus is used for coating and printing a pattern on the surface of the substrate 10; the substrate transfer device 1 is used to transfer the substrate 10 of the coated printed pattern into the irradiation range of the first group point laser light source array 2; The first group point laser light source array 2 outputs an optical signal corresponding to the shape of the first region according to the encoding information, and is used for exposure curing the first region, and the substrate transfer device 1 also It is used to transmit the substrate 10 after the first area is cured into the irradiation range of the second group point laser light source array 4, in this process, the first magnetic field 3 is applied to the coated printed area. It is installed on the lower side of the pattern, and moves synchronously with the substrate 10 by the first magnetic field transmission device 31, and the first magnetic field 3 transfers the ink of the uncured portion of the coated printed pattern. It is used to induce and change its angle. The second group point laser light source array 4 outputs an optical signal corresponding to the shape of the second region according to the encoding signal, and is used to light-harden the second region after the first magnetic field 3 acts, The substrate transfer device 1 is also used to transfer the substrate 10 into the irradiation range of the curing light source 6 after the second group point laser light source array 4 acts, in the process, the A second magnetic field 5 is installed on the lower side of the coated printed pattern and moves synchronously with the substrate 10 by the second magnetic field transmission device 51 , and the second magnetic field 5 is used to induce ink in the uncured portion of the pattern and change its angle; The curing light source 6 outputs an optical signal corresponding to the shape of the third region according to the encoding signal, and is used for exposure curing the third region after the second magnetic field is applied.

The first magnetic field 3 and the second magnetic field 5 are both synchronous magnetic fields, and the synchronous magnetic field is formed by being fixed to a flexible conveyor belt by an induction magnet or electromagnetic fitting clamp, and printing a coating on the substrate 10 . Aim the pattern.

The point laser light source array (2, 4) includes an encoding mechanism and an exposure mechanism, the encoding mechanism being used to generate encoding information, and the exposure mechanism determining the illumination range of the point laser light source array according to the encoding information. used to control lighting brightness; A point light source in the point laser light source array is a single or a plurality of point light sources, so that parallel movement of the point light source in a two-dimensional plane, a switch of the point light source in a two-dimensional plane, or parallel movement of the point light source in a two-dimensional plane By controlling over-switching, the portion corresponding to the pattern on the surface of the substrate is exposed and hardened.

Each laser tube in the point laser light source array controls the switching and adjusts the energy intensity, all through circuitry; The equivalent diameter or length of a rectangular side of a single point laser light source is in the range of 10ηM-10MM. The point laser light source array is a two-dimensional array light source or a one-dimensional line array.

The point laser light source array may be replaced with a controllable point light source array, and the collecting, collimating or projecting of each controllable point light source within the controllable point light source array may all coordinate switching through circuitry; The equivalent diameter or length of a rectangular side of a single point light source is in the range of 10ηM-10MM.

The manufacturing method includes the following steps.

In step S1, the pattern shown in FIG. 1 is coated and printed on the surface of the substrate by using a coating printing apparatus. In the coating printing ink used, a material induced through a magnetic field is contained, and the material has light curing properties. and the pattern is formed by intersecting and overlapping two pentagonal star patterns 100 and 200, the center 120 is overlapped, the peripheral edges do not overlap, and the pattern is distributed along the circumferential direction of the center 120 do.

In step S2, through the substrate transfer device 1, the pattern-coated substrate 10 is transferred within the irradiation range of the first group point laser light source array 2, and the first group point laser The light source array 2 outputs an optical signal having a shape corresponding to the center 120 of the pattern described above according to the encoding signal, irradiates the center 120 of the pattern, exposes the portion, and then cures. and hardening the magnetic pigment powder within the range of the center 120 to fix the angle, and at this time, parts other than the center 120 part of the two pentagonal stars 100 and 200, that is, the first pentagonal part and the second pentagonal part 2 A total of 10 corners of the pentagonal part are not all cured, as shown in FIG. 2 .

In step S3, through the substrate transfer device 1, the substrate 10 coated with the pattern after being processed in step S2 is continuously transferred, and at the same time one A first magnetic field 3 moving synchronously with the pattern is installed, and the coating printing material of the uncured pattern portion is re-guided during step S2 to change its angle, and the second group point laser light source array After reaching the irradiation range of (4), the transmission is stopped, and the second group point laser light source array 4, according to the encoding signal, is located outside the center 120 of the first five-pointed star 100 in FIG. 1 according to the encoding signal. Outputting one optical signal having a shape corresponding to the first pentagonal part, exposing and curing the first pentagonal part, and the magnetic pigment powder within the range of the first pentagonal part has an angle fixed by curing, in this case, 2 The pentagonal part is not hardened, and as shown in FIG. 3 , in order not to affect the illustration of the hardened part, the angle change that occurs after the second pentagonal part is induced by the first magnetic field 3 is shown in FIG. It should be explained that not shown.

In step S4, through a transmission mechanism, the substrate coated with the pattern after processing in step S3 is transferred, and at the same time, a second magnetic field moving synchronously with one of the patterns below the pattern. In the step (S3), the coating printing material of the second pentagonal part that has not been cured is re-guided, the angle is changed, and then the transmission is stopped, and the light source array of the third group point laser receives the encoded signal. Accordingly, an optical signal having a shape corresponding to the second pentagonal star is output, the second pentagonal part is exposed and cured, and the magnetic pigment powder within the range of the second pentagonal part is cured to have an angle fixed, and at this time, The center 120, the coating printing material in the first pentagonal portion and the second pentagonal portion are each cured at a unique angle, so that all patterns shown in FIG. 1 are fully exposed, and the entire pattern is cured to form a security pattern Bar, as shown in FIG. 4 . In this security pattern, when an angle change is observed, three different bright surfaces of the first pentagonal portion, the second pentagonal portion and the center 120 are continuously displayed.

In this embodiment, the center 120 corresponds to the first region, the first pentagonal portion corresponds to the second region, and the second pentagonal portion corresponds to the third region.

Example 2:

The present embodiment provides a security pattern capable of writing another variable encoding information, a manufacturing apparatus and a manufacturing method thereof, and is similar to Embodiment 1, except that the patterns are different, specifically, FIG. 5 As shown in , the pattern in this embodiment is one two-dimensional code.

The manufacturing method is as follows. The coating printing apparatus coats and prints one rectangle on the substrate surface, the point laser light source array outputs a pattern in the form of one black part in the rectangle according to the encoding signal, and the part is cured after exposure to light, and the magnetic field in the pattern is output. The pigment powder is angled by curing; At this time, the transmission mechanism continuously transmits the substrate of the pattern, and at the same time, a magnetic field synchronous with one substrate is installed on the lower side of the pattern, re-inducing the material inside the uncured pattern part, changing the angle, and exposure After completing the overall exposure to the pattern of the instrument, the entire pattern is cured and, after passing through this process, a machine-readable two-dimensional code can be formed.

The aforementioned array-type point light source can be controlled by encoding to form a variety of variable patterns, and the variable pattern is transferred to the pattern surface through exposure, so that a security pattern of variable encoding information of a series of one object one image code can form.

The advantage of this security pattern is that it can form very sharp changes in contrast, color, graphics, etc., can write a two-dimensional code that can be read by a smartphone, and can write an arbitrary pattern that can be read with a specific encryption. can

Example 3:

This embodiment provides a security pattern capable of writing another variable encoding information, and a manufacturing apparatus and manufacturing method thereof, which are similar to those of Embodiment 1, with the only difference being that the patterns are different, specifically, As shown in Fig. 6, the pattern of this embodiment is a two-dimensional code of the origin type.

The manufacturing method is as follows. The coating printing device coats and prints one 20*20 circular dot array on the substrate (QRcode positioning is also included in the pattern), the size of each circular dot is 0.9MM in diameter, and each laser dot is 1MM in diameter. the array outputs one pattern of an encoded two-dimensional dot array according to the encoding signal, the bright part is exposed and then cured, and the magnetic pigment powder in the pattern is angled by curing; The coated printed pattern is entered into a magnetic field, and the uncured part is induced at different angles, and then the whole is cured, and complete manufacture of the origin-type two-dimensional code is completed.

Example 4:

The present embodiment provides a security pattern capable of writing another variable encoding information, a manufacturing apparatus and a manufacturing method thereof, and is similar to Embodiment 1, except that the patterns are different and the induced magnetic fields used are different from each other. Another thing, specifically, the composite magnetic field used by this embodiment is composed of a plurality of magnetic poles and a clamp for fixing the magnetic poles.

The manufacturing process is as follows.

1. First, the outline of one starfish is coated and printed on the substrate, as shown in FIG. 7 .

2. Again, a composite magnetic field is used to induce a coated printed substrate, as shown in FIG. 8 .

The upper part of the complex magnetic field, that is, the position approaching the coated printed pattern, is a magnetic field with several small magnetic rings distributed, and the lower part of the complex magnetic field is a single strip-shaped columnar magnetic field, and a small magnetic field and a strip-shaped column The magnetic field is clamped by a clamp made of one non-magnetic material, placing it underneath the coated printed starfish outline.

3. After induction, through photocuring, a three-dimensional starfish pattern can be obtained in which the densely distributed ring-shaped light spots in the figure and the overall light pillar change, among which the white part is the columnar light pattern part, and the observation angle According to the change, the light fringes move in parallel, as shown in FIG. 9 .

Example 5:

The present embodiment provides an apparatus for manufacturing a security pattern capable of writing other variable encoding information, which is similar to the first embodiment, except that the distinguishing point is as shown in FIG. 11 , the first group point laser light source array (2) Previously, a group of synchronous magnetic fields 7 and a corresponding magnetic field transmission device 71 are installed under the substrate 10, and the substrate 10 is the first group point laser light source array 2 ), the coating is used to guide the ink in the printed pattern.

Example 6:

The present embodiment provides a method of manufacturing a security pattern capable of writing other variable encoding information, including the following steps.

In step S1, a substrate with a coated printed pattern is provided, wherein the coated printed pattern is in a cured state; The used coating printing ink paint has a liquefaction action with respect to the light source, that is, the exposed portion of the coating printed pattern is changed from a polymer to a low molecular weight, that is, from a solid state to a liquid state; At the same time, it provides a pattern liquefied light source, a magnetic field and an endpoint curing mechanism, wherein the pattern liquefied light source encodeably controls the illumination range and illumination brightness of the light source, thereby generating a liquefied light source pattern, wherein the magnetic field is installed in the pattern liquefied light source Then, the magnetic field is a magnetic field that moves synchronously through the substrate or a fixed magnetic field.

In step (S2), the coating printed pattern on the substrate is transmitted within the irradiation range of the pattern liquefied light source, and the liquefied light source pattern is transferred to the coated printed pattern, and the liquefied light source pattern among the coated printed patterns Change the corresponding area to a liquid state.

In step S3, the substrate is continuously transferred, and in the process of transferring, the magnetic field induces the coated printed pattern of the substrate, thereby re-directing the direction of the ink paint after liquefaction.

In step S4, the substrate is continuously transferred within the working range of the end-point solidification mechanism to harden the area after being induced again to form a new pattern.

In the manufacture of the security pattern capable of writing variable encoding information according to the present invention, the point light source array and the magnetic field are installed at intervals one by one according to the direction in which the substrate is transmitted, and between each two adjacent group point light source arrays And, between the last one group point light source array and the end point curing light source, and before the first group point light source array when the number of magnetic fields is N+1 group, all one group of magnetic fields are installed, Example 5 as described in Depending on the direction in which the substrate is transmitted, the heads of each magnetic field overlap or partially overlap the nearest point light source array or end point curing light source, as shown in FIG. 10 . The purpose of this design is that the orientation after induction can be maintained when the ink is cured after the magnetic field is induced, and the orientation is not disturbed or obscured by demagnetization. Another method is that the magnetic field and the point light source array do not overlap at all, and in the moving direction of the substrate, the end point of the magnetic field and the end point of the point light source array are connected or even spaced apart from each other, and the advantage of this design is that the magnetic field The action of the point light source array and the ink in the coated printed pattern does not affect each other.

Claims (17)

In a security pattern capable of writing variable encoding information,
A writable security pattern of variable encoding information, comprising a plurality of regions hardened in different directions, and wherein some or all of the plurality of regions include variable encoding information.
An apparatus for manufacturing a security pattern capable of writing variable encoding information, the apparatus comprising:
a coating printing apparatus, a substrate transfer apparatus, an N group point light source array, an N or N+1 group magnetic field, and one endpoint curing light source, wherein N=1; the N group point light source array and the N or N+1 group magnetic field are provided on the same side or opposite sides of the substrate transfer direction;
the coating printing device is used to coat and print a pattern on the substrate surface;
the substrate transfer device is used to transfer a pattern-coated substrate; Since each point light source array controls the illumination range and illumination brightness according to the real-time encoding information, the light signal corresponding to the encoding information is output as a coated printed pattern on the substrate that enters the irradiation range of the point light source array. and the ink in the corresponding area on the coated printed pattern is exposed and cured;
Each magnetic field is used to induce ink in the uncured portion of the coated printed pattern, all of which change its angle;
The end-point curing light source is used to realize complete exposure of the pattern by curing all uncured portions of the pattern after the N group point light source array and the N or N+1 group magnetic field are installed. A device for manufacturing a security pattern capable of writing variable encoding information.
3. The method of claim 2,
According to the direction in which the substrate is transferred, the point light source array and the magnetic field are installed at intervals one by one, between each two adjacent group point light source arrays, between the last one group point light source array and the end point curing light source, and the magnetic field When the quantity is N+1 groups, before the first group point light source array, a device for manufacturing a security pattern capable of writing variable encoding information, characterized in that all one group of magnetic fields are installed.
4. The method of claim 3,
According to the direction in which the substrate is transmitted, the head of each magnetic field overlaps or partially overlaps with the nearest point light source array.
5. The method according to any one of claims 2 to 4,
The magnetic field is a fixed magnetic field or a device for manufacturing a secure pattern capable of writing variable encoding information, characterized in that the synchronous long-term field transmitted synchronously with the substrate.
6. The method of claim 5,
The synchronous magnetic field is formed to be fixed to a flexible conveyor belt using an induction magnet or an electromagnetic clamping clamp, and a device for manufacturing a security pattern capable of writing variable encoding information, characterized in that the coated printed pattern on the substrate is aimed. .
6. The method of claim 5,
The synchronous magnetic field uses a multiple magnetic field complex superposition method, the magnetic force range of the magnetic field has a different magnetic moment depending on the size and location of the magnetic field, and according to the principle, a short-distance small magnetic field is added to the existing long-distance to add a complex magnetic field. An apparatus for manufacturing a security pattern capable of writing variable encoding information, characterized in that it acquires the effect of
3. The method of claim 2,
A device for manufacturing a security pattern capable of writing variable encoding information, characterized in that the minimum distance between the coated printed pattern and the magnetic field is 0.1MM-10CM.
3. The method of claim 2,
The point light source array includes an encoding mechanism and an exposure mechanism, wherein the encoding mechanism is used to generate encoding information, and the exposure mechanism is used to control an illumination range and illumination brightness of the point light source array according to the encoding information. become; The corresponding point light source is a single or a plurality of point light sources, and through translation and/or switching in a two-dimensional plane, a corresponding portion of the pattern of the substrate surface is exposed and hardened. A device that manufactures a writable security pattern.
10. The method of claim 9,
The point light source array is an apparatus for manufacturing a security pattern capable of writing variable encoding information, characterized in that the point laser light source array.
11. The method of claim 10,
Each laser tube in the point laser light source array controls switching and adjusts energy intensity, all through circuitry; An apparatus for manufacturing a secure pattern capable of writing variable encoding information, characterized in that the equivalent diameter of the single point laser light source or the length of the rectangular side is in the range of 10ηM-10MM.
12. The method of claim 11,
The point laser light source array is a two-dimensional array light source or a one-dimensional line array, characterized in that the variable encoding information can be written in the manufacturing apparatus of the security pattern.
3. The method of claim 2,
the point light source array is a controllable point light source array, in which condensing, collimating or projecting of each controllable point light source all controls switching through a circuit; An apparatus for manufacturing a secure pattern capable of writing variable encoding information, characterized in that the equivalent diameter of a single point light source or the length of a rectangular side is in the range of 10ηM-10MM.
3. The method of claim 2,
The point light source array further includes a controllable light barrier installed between the point light source array and the substrate, and when the light source of the point light source array does not change, by controlling the degree of opening of the controllable light barrier, the point light source An apparatus for manufacturing a security pattern capable of writing variable encoding information, which realizes exposure control of an array.
6. The method of claim 5,
The number of point light source arrays is two, all of which are installed on the upper side of the substrate, and the number of synchronous magnetic fields is two, all of which are installed on the lower side of the substrate;
The substrate transfer device is used to transfer a coated printed substrate within an irradiation range of a first point light source array, and the first point light source array includes, according to encoding information, a first area shape to be displayed on a coated printed pattern and used to output an optical signal corresponding to a light-dark pattern, and after the first area of the coated printed pattern is exposure-cured, the substrate transfer device continues to transmit the substrate, and the first synchronization magnetic field is the first synchronization moved synchronously with the substrate by a magnetic field transmission device, wherein the first synchronous magnetic field is used to induce an uncured portion of the coated printed pattern, ie, ink other than the first area, to change the angle;
The substrate transfer device is also used to transfer the substrate after the first region is cured into an irradiation range of a second point light source array, wherein the second point light source array is displayed in a coated printed pattern according to the encoding information. outputting an optical signal corresponding to the shape of the second region and the light and dark pattern, and used for exposing and curing the second region of the coated printed pattern after the first synchronous magnetic field is applied;
The substrate transfer device is also used to transfer the substrate into the irradiation range of the endpoint curing light source after the second point light source array acts, in this process, a second synchronous magnetic field is generated by the second synchronous magnetic field transfer device moving synchronously with the substrate, the second synchronous magnetic field is used to induce ink in an uncured portion of the coated printed pattern, that is, in an area other than the first area and the second area, to change the angle; The end-point curing light source is an apparatus for manufacturing a security pattern capable of writing variable encoding information, characterized in that it is used for exposure curing the area after the second synchronization magnetic field is applied.
A method of manufacturing a security pattern capable of writing variable encoding information, the method comprising:
adding the inducible material to the coating printing ink paint and coating printing on the substrate to form a light cured coating printed pattern; At the same time, the N group point light source array and the N or N+1 group magnetic field are provided, and the N group point light source array and the N or N+1 group magnetic field are installed on the same side or opposite sides of the substrate transmission direction, N=1, step (S1);
When the substrate is transferred, and the quantity of the magnetic field is N+1 groups, in the process of transferring the substrate, the magnetic field of the first group first induces the coated printed pattern, and the coated printed pattern is again converted to the first point. transmitted within the irradiation range of the light source array, and when the quantity of the magnetic field is N group, the coated printed pattern is directly transmitted into the irradiation range of the first point light source array, and the first point light source array is a pattern light source according to the encoding information forming a, and the pattern light source exposes the coated printed pattern within the irradiation range of the point light source array to cure a portion corresponding to the pattern light source among the coated printed patterns, and the pattern of the pattern light source is coated with the printed pattern to achieve the effect of transitioning to a pattern, a step (S2);
The substrate is continuously transferred, during which a magnetic field corresponding to the coated printed pattern induces an uncured portion of the coated printed pattern to reach within the irradiation range of the next encodeable point light source array, The encodeable point light source array forms another pattern light source according to the encoding information, and the other pattern light source exposes the coated printed pattern within the irradiation range of the point light source array to light the other of the coated printed patterns. curing a portion corresponding to one pattern light source (S3);
If necessary, step S4, repeating step S3 until the substrate sequentially passes through the N group point light source array and the N or N+1 group magnetic field;
The coated printed pattern is continuously transmitted within the irradiation range of the end-point curing light source, and the uncured portion of the coated printed pattern is completely cured, including a step (S5). A method of manufacturing a security pattern.
A method of manufacturing a security pattern capable of writing variable encoding information, the method comprising:
A substrate is provided having a coated printed pattern, wherein the coated printed pattern is in a cured state; The used coating printing ink paint has a liquefaction action with respect to the light source, that is, the exposed portion of the coating printed pattern is changed from a polymer to a low molecular weight, that is, from a solid state to a liquid state; At the same time, it provides a pattern liquefied light source, a magnetic field and an endpoint curing mechanism, wherein the pattern liquefied light source encodeably controls the illumination range and illumination brightness of the light source, thereby generating a liquefied light source pattern, wherein the magnetic field is installed in the pattern liquefied light source Then, the magnetic field is a magnetic field that moves synchronously with the substrate or a fixed magnetic field, step (S1);
The coating printed pattern on the substrate is transferred within the irradiation range of the pattern liquefied light source, and the liquefied light source pattern is transferred to the coated printed pattern, and the region corresponding to the liquefied light source pattern among the coated printed patterns is in a liquid state. changing. step (S2) and;
The substrate is continuously transferred, and in the process of transferring, the magnetic field induces a coated printed pattern of the substrate, thereby re-directing the direction of the ink paint after liquefaction (S3);
and the substrate is continuously transferred within the working range of the endpoint solidification mechanism, and the region after being induced again is hardened to form a new pattern (S4). Methods of manufacturing possible security patterns.

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